3KP210中文资料

Product Specification: SP0102 Series (Generation II)This document applies the following SiSonic Model Numbers:SP0102NC3-2SP0102NC3-3SiSonic microphone was developed as a cost effective alternative to traditional electret condensermicrophones. Provided on tape-and-reel, SiSonic is ideally suited for high volume applications. It can be processed directly to a customer’s PCB using standard automatic pick-and-place equipment, and surface mounted via standard solder reflow equipment.Microphone Dimensional Layoutmm< 0.1Coplanaritygrams < 0.5Weight 0.050.050.15Tol. (+/-)mm 3.76Width mm 6.15Length mm 1.45Height Units Dim.Item Microphone Pin OutputRecommended PCBLand LayoutProduct Specifications Test Conditions: +20ºC, 60-70% R.H.dBA SPL35A-weightedENL Typical Input ReferredNoiseºC +100-40Operating Temperature ºC+100-40Storage TemperaturedBAt 100dB SPL, THD < 1%At 115dB SPL, THD = < 10%Maximum Input SoundLevelHz100 –10,000Frequency RangeOmni-directional Directivity dBNo Change Across Voltage RangeChange in sensitivity over5.5v to 1.5vSensitivity Loss acrossVoltage Max.Nom.Min.V 5.51.5VsSupply Voltage dB5955@ 1kHz (0dB=1V/Pa)S/N Signal to Noise Ratio mA 0.2500.100across 1.5 to 5.5 volts I DSS Current Consumption Ω100@ 1kHz (0dB=1V/Pa)Z OUT Output impedance dB -38-42-46@ 1kHz (0dB=1V/Pa)S Sensitivity UnitLimitsCondition SymbolFrequency Response CurvePackaging Specifications Carrier –Tape Detail“L” –directionPolarity of part1 year storage (original packaging, low humidity)Storage Life Label applied to externalpackage and direct to reel. Per JEDEC.Label800mm or minimum of 100 empty pocketsLeader Length Available in 7” or 13” diameter.Tape & Reel reference Reliability section# of Reflow Passes Gold (27u”) over Nickel (150u”) Typical Terminal Pads 260ºC for maximum 30 seconds Solder Reflow Solderability Characteristics (** No board washing after reflow **)NOTE: All devices are lead-free, and compatible with lead-free reflow profile.4,5001,200Qty per Reel 10 & 33pF13”-3SP0102NC310 & 33pF 7”-2SP0102NC3Capacitor Config.Reel DiameterSuffixModel Number Reflow Profile(Maximum Conditions)+-+VrefR1R2External Gain (set by customer) = -R1/R2Term. 4Term. 3Term. 1•••Dotted Section Represents SiSonic MicrophoneRecommended Interface CircuitTested to greater than 5,000g (IEC 68-2-27, Ea).Mechanical Shock Microphone is tested to 5 passes through reflow oven, with microphone mounted upside-down under conditions of 260ºC for 30 seconds maximum.ReflowTested to 8kV direct contact discharge or 15kV air discharge as specified by IEC 1000-4-2, level 3 and level 4.Electrostatic Discharge Microphone unit must maintain sensitivity after storage at –40ºC for 1,000 hours. (IEC 68-2-1 Test Aa)Low Temperature Storage Test Microphone unit must maintain sensitivity after storage at +105ºC for 1,000 hours. (IEC 68-2-2 Test Ba)High Temperature Storage Test After test conditions are performed, the sensitivity of the microphone shall not deviate more than 3dB from its initial value.Note:Microphone unit must operate within sensitivity specifications for 16 hours at –40ºC. (IEC 68-2-1 Test Aa)Low Temperature Operating Test Microphone unit must operate under test condition: 4 cycles, from 20 to 2,000 Hz in each direction (x,y,z), 48 minutes, using peak acceleration of 20g (+20%, -0%). (MIL 883E, method 2007.2, A)Vibration TestTested under Bias at 85ºC/85% R.H. for 270 hours. (JESD22-A101A-B)Humidity Test Microphone unit must operate within sensitivity specifications for 16 hours at 105ºC. (IEC 68-2-2 Test Ba)High Temperature Operating Test Microphone unit must operate when exposed to air-to-air thermal shock 100 cycles, from –40ºC to +125ºC. (IEC 68-2-4),Thermal Shock Reliability。

Solid-state Relay G3CN PCB-mounting SSR for FA EquipmentRequiring High Reliability Array Wide I/O voltage range: 3 to 28 VDC input and 75 to264 VAC output or 3 to 28 VDC input and 3 to52.8 VDC output.Two load currents available: 2 A and 3 AFlat and vertical models available for a variety ofapplications.Approved by UL and CSA.*V ertical models.**When ordering, specify the input voltage171RatingsInputNote:The input impedance is measured at the maximum value of the operating voltage. For example, with the model rated at 4 to 24 VDC, the input impedance is measured at 28 VDC.OutputCharacteristics172173Load Current vs. Ambient Temperature CharacteristicsG3CN-202P(1)/-202PL(1)/-DX02P(1)-USAmbient temperature (°C)L o a d c u r r e n t (A )G3CN-203P(1)/-203PL(1)/-DX03P(1)-USL o a d c u r r e n t (A )Ambient temperature (°C)G3CN-203P(1)/-203PL(1)-US G3CN-DX02P(1)-USI n r u s h c u r r e n t (A . P e a k )Energizing time (ms)I n r u s h c u r r e n t (A . P e a k )Energizing time (ms)Inrush Current ResistivityNon-repetitive (Keep the inrush current to half the rated value if it occurs repetitively .)G3CN-202P(1)/-202PL(1)-USG3CN-DX03P(1)-USI n r u s h c u r r e n t (A . P e a k )I n r u s h c u r r e n t (A . P e a k )Energizing time (ms)Energizing time (ms)174T erminal Arrangement/Internal Connections (Bottom View)Flat ModelG3CN-20j P/-20j PL/-DX0j PVertical ModelG3CN-20j P1/-20j PL1/-DX0j P1Note:Values in parentheses apply to the DC-load versions.Note:Values in parentheses apply to the DC-load versions.0.433 max.25 max.14.5max.20 max. 1.5 max.25±0.512.5±0.510±0.50.70.70.70.433 max.14 max.26.5 max.32 max.1.5 max.27.5±0.5(17.5)5±0.53±1Four 1.2-dia.holes2512.55(17.5)527.5Two, 2-dia.holesTwo, 4 dia.holesTwo, 2-dia.holesFour 1.2-dia.holesPatternPattern10Terminal Arrangement/Mounting Holes (Bottom View)T erminal Arrangement/Internal Connections (Bottom View)T erminal Arrangement/Mounting Holes (Bottom View)5±0.5175ConnectionWith the SSR for DC switching, the load can be connected to either positive or negative output terminal of the SSR.Protective ComponentSince the SSR does not incorporate an overvoltage absorption component, be sure to connect an overvoltage absorption compo -nent when using the SSR under an inductive load.ALL DIMENSIONS SHOWN ARE IN MILLIMETERS.To convert millimeters into inches, multiply by 0.03937. T o convert grams into ounces, multiply by 0.03527.Cat. No. K063-E1-2A。

DA221中文资料Diodes1/4Switching diodeDA221M / DA221 / DA204U / DA204K DA228U / DA228K /UMR12Nz Applications Bias circuitsProtection circuitsz Features1) Three types of packages are available. (VMD3, EMD3, UMD3, SMD3)2) Two diode elements are connected in series (V F × 2) per circuit.z ConstructionSilicon epitaxial planarz Circuitz External dimensions (Unit : mm)Diodes2/4z MarkingUMD3DA204UDA228U UMD6UMR12NR12SMD3DA204KDA228KK BUKBU EMD3DA221KVMD3DA221Mz Absolute maximum ratings (T a=25°C)Type V RM (V)V R (V)I FM (mA)I O (mA)I surge (mA)(1μs)(TOTAL)Pd(mW)Tj(°C)Tstg(°C)DA2212020200100300150150?55 to +150DA221M 2020200100300150150?55 to +150DA204U 2020200100300200150?55 to +150DA228K 8080200100300200150?55 to +150UMR12N808020010030020015055 to +15055 to +150DA228U 8080200100300200150?55 to +150DA204K 2020200100300200150Peak reverse voltage Peak forward current Mean rectifying current Surge current Power dissipation Junction temperatureStoragetemperature DC reverse voltagez Electrical characteristics (T a=25°C)TypeForward voltageV F (V)Max.I R (μA)Max.Reverse current Fig.Cond.Cond.I F (mA)V R (V)DA221 1.0100.115 1 to 4DA221M 1.0100.115 1 to 45 to 9UMR12N1.210080DA204U 1.0100.115 1 to 40.1DA228U 1.210080 5 to 90.11.01015DA204K 1 to 40.1DA228K 1.210080 5 to 9Diodes3/4z Electrical characteristic curves (T a=25°C) (DA221, DA204U, DA204K) …Fig.1 to 4T a =125°CD1D1+D20.40.8 1.2 1.6 2.0 2.41001011.00.0175°C5°C25°C125°C75°C25°C25°CF O R W A R D C U R R E N T : I F (m A )FORWARD VOLTAGE : V F (V)Fig.1 Forward characteristicsF O R W A R D C U R R E N T : I F (m A )FORWARD VOLTAGE : V F (V)Fig.2 Forward characteristicsD2 125°CD1 100°C D2 100°CD1 75°C D2 75°C51015200.010.1110100D1 Ta=125°CR E V E R S E CU R R E N T : I R (n A )REVERSE VOLTAGE : V R (V)Fig.3 Reverse characteristics12510C A P A C I T A N C E B E T W E E N T E R M I N A L S : C T (p F )REVERSE VOLTAGE : V R (V)Fig.4 Capacitance between terminals characteristicsDiodes4/4(DA228U, DA228K, UMR12N) …Fig.5 to 9F O R W A R D C U R R E N T : I F (m A )FORWARD VOLTAGE : V F (V)Fig.5 Forward characteristics F O R W A R D C U R R E N T : I F(m A )FORWARD VOLTAGE : V F (V)Fig.6 Forward characteristics R E V E R S E C U R R EN T : I R (n A )REVERSE VOLTAGE : V R (V)Fig.7 Reverse characteristicsR E V E R S E C U R RE N T : I R (n A )REVERSE VOLTAGE : V R (V)Fig.8 Reverse characteristics110C A P A C I T A N C E B E T W E E N T E R M I N A L S : C T (p F )REVERSE VOLTAGE : V R (V)Fig.9 Capacitance between terminals characteristicsAppendixAbout Export Control Order in JapanProducts described herein are the objects of controlled goods in Annex 1 (Item 16) of Export Trade ControlOrder in Japan.In case of export from Japan, please confirm if it applies to "objective" criteria or an "informed" (by MITI clause)on the basis of "catch all controls for Non-Proliferation of Weapons of Mass Destruction.Appendix1-Rev1.0。

D escriptionT he 3M™ 8710, 8210, 8812 and 8822 Particulate Respirators provide eff ective respiratory protection for use in industries where workers will be exposed to dust particles and/or non-volatile liquid particles.T ested and certifi ed to AS/NZS 1716:2003.•T raditional convex shape, with nose clip and twin strap design.•D urable, collapse resistant inner shell.• R eliable, eff ective protection against fi ne particles.• 3M™ Advanced Electret Filter Material gives eff ective fi ltration •with low breathing resistance for consistent high quality performance. 3M™ Cool Flow™ exhalation valve off ers improved comfort in • h ot humid environments and/or where work is hard and physical*. M aterialsT he following materials are used in the production of the 8710, 8210, 8812 and 8822 Particulate Respirators:S traps • 8812, 8822 – Polyisoprene 8710 and 8210 – Thermoplastic Elastomer S taples • 8812, 8822 – Steel 8710 and 8210 – no staplesN ose Foam • P olyester N ose Clip • 8210 – Aluminium 8710, 8812, 8822 – Steel F ilter •P olyester / Polypropylene V alve* • P olypropylene V alve diaphragm* • P olyisopreneThese products do not contain components made from natural rubber latex.M aximum mass of products:• U nvalved (8710 & 8210) = 8g •V alved (8812 & 8822) =13gS tandardsThese products meet the requirements of Australian New Zealand Standard AS/NZS 1716:2003, Respiratory protective devices. They should be used to protect the wearer from solid and non-volatile liquid particles only.P articulate Filter Respirators are classifi ed by fi ltering effi ciency and maximum total inward leakage performance (P1 & P2), also by inhalation resistance.P 1 fi lters are indended for use against mechanically generatedparticulates such as those generated from sanding, grinding, drilling, sweeping etc.P2 fi lters are intended for use against both mechanically and thermally generated particulates e.g. welding, brazing etc. P2 fi lters may also help reduce breathing in pathogenic biological airborne particulates such as infl uenza virus.A pprovalsT hese respirators have been produced to comply with the requirements of the Australian / New Zealand Standard AS/NZS 1716:2003 under an agreed production certifi cation scheme operated during manufacture in accordance with the SAI Global StandardsMark programme.A pplicationsT hese respirators are suitable for use in concentrations of solid andnon-volatile liquid particles up to the following limits:E S = Exposure Standard Respiratory protection is only eff ective if it is correctly selected, fi tted and worn throughout the time when the wearer is exposed to hazards.3M ™8710, 8210, 8812 and 8822P articulate Respirators* 8812 and 8822 models onlyDatasheetS electionGuidethe most appropriate personal protective equipment (PPE) will depend on the particular situation and should be made only by a competent person knowledgeable of the assessed risks, actual working conditions and limitations of PPE. Details regarding performance and limitations are set out on the product packaging and user information. If in doubt, contact a safety professional or 3M.For respiratory training and advice please contact your local 3M representative.S torage and TransportationT he 3M™ 8710, 8210, 8812 and 8822 Particulate Respirators have a shelf life of 3 years. End of shelf life is marked on the product packaging. Before initial use, always check that the product is within the stated shelf life (use by date). Product should be stored in clean, dry conditions within the temperature range: – 20°C to + 25°C with a maximum relative humidity of <80%. When storing or transporting this product use original packaging provided.D isposalC ontaminated products should be disposed as hazardous waste in accordance with local regulations.Fitting Instructions 8710 and 8210 onlyS ee Figure 1. a nd 1. 2 . Pre-stretch around entire length of each strap bypulling at 3cm intervals between both hands.C up respirator in one hand with nosepiece at fi ngertips, allow 3. headbands to hang freely below hand. H old respirator under chin, with nosepiece up.4. L ocate the upper strap across the crown of the head and the 5. lower strap below the ears. S traps must not be twisted.6. U sing both hands, mould noseclip to the shape of the lower7. part of the nose to ensure a close fi t and good seal. Pinching the noseclip using only one hand may result in less eff ective respirator performance.T he seal of the respirator on the face should be fi t-checked 8. before entering the workplace.F igure 18812 and 8822 onlyS ee Figure 2. C up respirator in one hand with nosepiece at fi ngertips, allow1. headbands to hang freely below hand. H old respirator under chin, with nosepiece up.2. L ocate the upper strap across the crown of the head and the3. lower strap below the ears. S traps must not be twisted.4. U sing both hands, mould noseclip to the shape of the lower5. part of the nose to ensure a close fi t and good seal. Pinching the noseclip using only one hand may result in less eff ective respirator performance.T he seal of the respirator on the face should be fi t-checked 6. before entering the workplace.F igure 2F it CheckC over the front of the respirator with both hands being careful1. not to disturb the fi t of the respirator.(a) UNVALVED respirator - EXHALE sharply;2. (b) VALVED respirator - INHALE sharply.I f air leaks around the nose, re-adjust the noseclip to 3. eliminate leakage. Repeat the above fi t check.I f air leaks at the respirator edges, work the straps back 4. along the sides of the head to eliminate leakage. Repeat the above fi t check.I f you CANNOT achieve a proper fi t DO NOT enter the hazardous area. S ee your supervisor . U sers should be fi t tested in accordance with AS/NZS 1715. F or information regarding fi t testing procedures, please contact 3M.Please recycle.© 3M 2010. All rights reserved.Important Notice3M does not accept liability of any kind, be it direct or consequential (including, but not limited to, loss of profi ts, business and/or goodwill)arising from reliance upon any information herein provided by 3M. The user is responsible for determining the suitability of the products for their intended use. Nothing in this statement will be deemed to exclude or restrict 3M’s liability for death or personal injury arising from its negligence.Occupational Health andEnvironmental Safety Division 3M Australia Pty Ltd950 Pacifi c Highway Pymble NSW 2073Phone: 136 136Fax: 02 9498 9616TechAssist Helpline: 1800 024 464E-mail:******************.au Website: /au/ohsOccupational Health and Environmental Safety Division 3M New Zealand Ltd94 Apollo Drive, Albany,North Shore City, 0632 Tech Helpline: 0800 364 357Customer services: 0800 252 627Fax: 0800 367 253E-mail:*****************.com Website : /safetyE U _M A S T E R _018710 respirator8210 respirator8812 respirator8822respiratorW arnings and Use LimitationsA lways be sure that the complete product is:• - Suitable for the application;- Fitted correctly;- Worn during all periods of exposure;- Replaced when necessary. P roper selection, training, use and appropriate maintenance are • essential in order for the product to help protect the wearer from certain airborne contaminants. F ailure to follow all instructions on the use of these respiratory • protection products and/or failure to properly wear the complete product during all periods of exposure may adversely aff ect the wearer’s health, lead to severe or life threatening illness or permanent disability. F or suitability and proper, use follow local regulations, refer to all • information supplied or contact an occupational hygienist, safety professional or 3M representative on the Tech Assist Helpline 3M Australia 1800 024 464, 3M New Zealand 0800 364 357. B efore use, the wearer must be trained in use of the complete • product in accordance with applicable Health and Safety standards/guidance.T hese products do not contain components made from natural • rubber latex. T hese products do not protect against gases/vapours.• D o not use in atmospheres containing less than 19.5% oxygen. • (3M defi nition. Individual countries may apply their own limits on oxygen defi ciency.Seek advice if in doubt). D o not use for respiratory protection against atmospheric contami-• nants/concentrations which are unknown or immediately danger-ous to life and health (IDLH). D o not use with beards or other facial hair that may inhibit contact between the face and the product thus preventing a good seal. L eave the contaminated area immediately if:• a) Breathing becomes diffi cult.b) Dizziness or other distress occurs. D iscard and replace the respirator if it becomes damaged,• breathing resistance becomes excessive or at the end of the shift. N ever alter, modify or repair this device.• I n case of intended use in explosive atmospheres, contact 3M.• P roductRange。

Transmissive Optical Sensor with Phototransistor OutputTCST2103, TCST2202, TCST2300Vishay SemiconductorsDESCRIPTIONThe TCST2103, TCST2202, and TCST2300 are transmissive sensors that include an infrared emitter and phototransistor, located face-to-face on the optical axes in a leaded package which blocks visible light. These part numbers include options for aperture width.FEATURES•Package type: leaded •Detector type: phototransistor•Dimensions (L x W x H in mm): 24.5 x 6.3 x 10.8•Gap (in mm): 3.1•Typical output current under test: C = 4 mA (TCST2103)•Typical output current under test: I C = 2 mA (TCST2202)•Typical output current under test: I C = 0.5 mA (TCST2300)•Daylight blocking filter •Emitter wavelength: 950 nm •Lead (Pb)-free soldering released•Compliant to RoHS directive 2002/95/EC and in accordance to WEEE 2002/96/ECAPPLICATIONS•Optical switch •Photo interrupter •Counter •EncoderNote(1)Conditions like in table basic characteristics/couplerNote(1)MOQ: minimum order quantity19180_4PRODUCT SUMMARYPART NUMBER GAP WIDTH(mm)APERTURE WIDTH(mm)TYPICAL OUTPUT CURRENTUNDER TEST (1)(mA)DAYLIGHTBLOCKING FILTER INTEGRATEDTCST2103 3.114Yes TCST2202 3.10.52Yes TCST23003.10.250.5YesORDERING INFORMATIONORDERING CODE PACKAGINGVOLUME (1)REMARKS TCST2103Tube MOQ: 1020 pcs, 85 pcs/tube With mounting flange TCST2202Tube MOQ: 1020 pcs, 85 pcs/tube With mounting flange TCST2300TubeMOQ: 1020 pcs, 85 pcs/tubeWith mounting flangeABSOLUTE MAXIMUM RATINGS (1)PARAMETER TEST CONDITIONSYMBOLVALUEUNITCOUPLERTotal power dissipation T amb ≤ 25 °CP tot 250mW Ambient temperature range T amb - 55 to + 85°C Storage temperature range T stg - 55 to + 100°C Soldering temperatureDistance to package: 2 mm; t ≤ 5 sT sd260°CTCST2103, TCST2202, TCST2300Vishay SemiconductorsTransmissive Optical Sensor withPhototransistor OutputNote (1)T amb = 25 °C, unless otherwise specifiedABSOLUTE MAXIMUM RATINGSFig. 1 - Power Dissipation Limit vs. Ambient TemperatureINPUT (EMITTER)Reverse voltage V R 6V Forward current I F 60mA Forward surge current t p ≤ 10 µs I FSM 3A Power dissipation T amb ≤ 25 °CP V 100mW Junction temperature T j100°COUTPUT (DETECTOR)Collector emitter voltage V CEO 70V Emitter collector voltage V ECO 7V Collector peak current t p /T = 0.5, t p≤ 10 msI CM 200mA Power dissipation T amb ≤ 25 °CP V 150mW Junction temperatureT j100°CABSOLUTE MAXIMUM RATINGS (1)PARAMETER TEST CONDITIONSYMBOLVALUEUNITBASIC CHARACTERISTICS (1)PARAMETER TEST CONDITIONPARTSYMBOLMIN.TYP.MAX.UNITCOUPLERCurrent transfer ratioV CE = 5 V, I F = 20 mATCST2103CTR 1020%TCST2202CTR 510%TCST2300CTR 1.25 2.5%Collector currentV CE = 5 V, I F = 20 mA TCST2103I C 24mA TCST2202I C 12mA TCST2300I C 0.250.5mA Collector emitter saturationvoltageI F = 20 mA, I C = 1 mA TCST2103V CEsat 0.4V I F = 20 mA, I C = 0.5 mA TCST2202V CEsat 0.4V I F = 20 mA, I C = 0.1 mA TCST2300V CEsat 0.4V Resolution, path of the shutter crossing the radiant sensitive zoneI Crel = 10 % to 90 %TCST2103s 0.6mm TCST2202s 0.4mm TCST2300s0.2mmTCST2103, TCST2202, TCST2300T ransmissive Optical Sensor withPhototransistor OutputVishay SemiconductorsNote (1)T amb = 25 °C, unless otherwise specifiedFig. 2 - Test Circuit for t on and t offFig. 3 - Switching TimesBASIC CHARACTERISTICST amb = 25°C, unless otherwise specifiedFig. 4 - Forward Current vs. Forward Voltage Fig. 5 - Relative Current Transfer Ratio vs. Ambient TemperatureINPUT (EMITTER)Forward voltage I F = 60 mA V F 1.25 1.6V Junction capacitance V R = 0 V, f = 1 MHzC j50pFOUTPUT (DETECTOR)Collector emitter voltage I C = 1 mA V CEO 70V Emitter collector voltage I E = 10 µAV ECO 7V Collector dark currentV CE = 25 V, I F = 0 A, E = 0 lxI CEO100nASWITCHING CHARACTERISTICS Turn-on time I C = 2 mA, V S = 5 V,R L = 100 Ω (see figure 2)t on 10µs Turn-off timeI C = 2 mA, V S = 5 V,R L = 100 Ω (see figure 2)t off8µsBASIC CHARACTERISTICS (1)PARAMETER TEST CONDITIONPARTSYMBOLMIN.TYP.MAX.UNIT10 %90 %100 %I FI C t p P u lse d u ration t d Delay time t rRise time t on (= t d + t r ) T u rn-on timet s Storage time t fFall time t off (= t s + t f )T u rn-off time96 11698TCST2103, TCST2202, TCST2300Vishay Semiconductors Transmissive Optical Sensor withPhototransistor OutputFig. 6 - Collector Dark Current vs. Ambient Temperature Fig. 7 - Collector Current vs. Forward Current Fig. 8 - Collector Current vs. Collector Emitter VoltageFig. 9 - Current Transfer Ratio vs. Forward Current Fig. 10 - Turn-off/Turn-on Time vs. Collector Current Fig. 11 - Relative Collector Current vs. DisplacementTCST2103, TCST2202, TCST2300T ransmissive Optical Sensor withPhototransistor OutputVishay SemiconductorsFig. 12 - Relative Collector Current vs. Displacement Fig. 13 - Relative Collector Current vs. DisplacementPACKAGE DIMENSIONS in millimetersTCST2103, TCST2202, TCST2300Vishay Semiconductors Transmissive Optical Sensor withPhototransistor Output TUBE DIMENSIONS in millimetersPackaging and Ordering InformationPackaging and Ordering InformationVishay SemiconductorsNotes(1)MOQ: minimum order quantity (2)Please refer to datasheetsTUBE SPECIFICATION FIGURESFig. 1PART NUMBER MOQ (1)PCS PER TUBETUBE SPEC.(FIGURE)CONSTITUENTS(FORMS)CNY70400080128TCPT1300X012000Reel (2)29TCRT10001000Bulk -26TCRT10101000Bulk -26TCRT5000450050227TCRT5000L 240048327TCST1030520065524TCST1030L 260065624TCST1103102085424TCST1202102085424TCST1230480060724TCST1300102085424TCST2103102085424TCST2202102085424TCST2300102085424TCST5250486030824TCUT1300X012000Reel (2)29TCZT8020-PAER2500Bulk-22Packaging and Ordering InformationVishay Semiconductors Packaging and Ordering InformationFig. 2Fig. 3Packaging and Ordering Information Packaging and Ordering Information Vishay SemiconductorsFig. 4Fig. 5Packaging and Ordering InformationVishay Semiconductors Packaging and Ordering InformationFig. 6Fig. 7分销商库存信息: VISHAYTCST2103。

RJK0383DPASilicon N Channel Power MOS FET with Schottky Barrier Diode High Speed Power SwitchingREJ03G1723-010192. Value at Tch = 25°C, Rg ≥ 50 Ω3. Tc = 25°CElectrical Characteristics• MOS1(Ta = 25°C)Item Symbol Min Typ Max Unit Test ConditionsDrain to source breakdown voltage V (BR)DSS 30 — — V I D = 10 mA, V GS = 0 Gate to source leak current I GSS — — ±0.1 µA V GS = ±20 V, V DS = 0 Zero gate voltage drain current I DSS — — 1 µA V DS = 30 V, V GS = 0 Gate to source cutoff voltage V GS(off) 1.2 — 2.5 V V DS = 10 V, I D = 1 mAR DS(on) — 8.5 11.1 m Ω I D = 7.5 A, V GS = 10 V Note4 Static drain to source on stateresistance R DS(on) — 12 16.8 m Ω I D = 7.5 A, V GS = 4.5 V Note4Forward transfer admittance |y fs | — TBD — S I D = 7.5 A, V DS = 10 V Note4 Input capacitance Ciss — 1010 — pF Output capacitance Coss — 190 — pFReverse transfer capacitance Crss — 75 — pF V DS = 10 VV GS = 0 f = 1 MHz Gate Resistance Rg — 1.2 — Ω Total gate charge Qg — 6.8 — nC Gate to source charge Qgs — 2.5 — nC Gate to drain charge Qgd — 1.5 — nC V DD = 10 V V GS = 4.5 V I D = 15 A Turn-on delay timet d(on) — TBD — ns Rise timet r — TBD — nsTurn-off delay time t d(off) — TBD — nsFall timet f — TBD — nsV GS =10 V, I D = 7.5 AV DD ≅ 10 V R L = 1.33 Ω R g = 4.7 Ω Body–drain diode forward voltage V DF — 0.84 1.10 V I F = 15 A, V GS = 0 Note4Body–drain diode reverse recovery time t rr — 20 — ns I F =15 A, V GS = 0di F / dt = 100 A/µsNotes: 4. Pulse test• MOS2(Ta = 25°C)Item Symbol Min Typ Max Unit Test ConditionsDrain to source breakdown voltage V (BR)DSS 30 — — V I D = 10 mA, V GS = 0 Gate to source leak current I GSS — — ±0.1 µA V GS = ±20 V, V DS = 0 Zero gate voltage drain current I DSS — — 1 mA V DS = 30 V, V GS = 0 Gate to source cutoff voltage V GS(off) 1.2 — 2.5 V V DS = 10 V, I D =1 mAR DS(on) — 2.5 3.3 m Ω I D =22.5 A, V GS = 10 V Note4 Static drain to source on stateresistance R DS(on) — 3.7 5.2 m Ω I D = 22.5 A, V GS = 4.5 V Note4Forward transfer admittance |y fs | — TBD — S I D = 22.5 A, V DS = 10 V Note4 Input capacitance Ciss — 3200 — pF Output capacitance Coss — 720 — pFReverse transfer capacitance Crss — 300 — pF V DS = 10 VV GS = 0 f = 1 MHz Gate Resistance Rg — 1.5 — Ω Total gate charge Qg — 20 — nC Gate to source charge Qgs — 8.6 — nC Gate to drain charge Qgd — 6.5 — nC V DD = 10 V V GS = 4.5 V I D = 45 A Turn-on delay time t d(on) — TBD — ns Rise timet r — TBD — nsTurn-off delay timet d(off) — TBD — nsFall timet f — TBD — nsV GS = 10 V, I D = 22.5 AV DD ≅ 10 V R L = 0.44 Ω R g = 4.7 Ω Schottky Barrier diode forward voltage V F — 0.36 — V I F = 2 A, V GS = 0 Note4Body–drain diode reverse recovery time t rr — 30 — ns I F = 45 A, V GS = 0di F / dt = 100 A/µsNotes: 4. Pulse testPackage DimensionsRefer to "/en/network " for the latest and detailed information.Renesas Technology America, Inc.450 Holger Way, San Jose, CA 95134-1368, U.S.A Tel: <1> (408) 382-7500, Fax: <1> (408) 382-7501Renesas Technology Europe LimitedDukes Meadow, Millboard Road, Bourne End, Buckinghamshire, SL8 5FH, U.K.Tel: <44> (1628) 585-100, Fax: <44> (1628) 585-900Renesas Technology (Shanghai) Co., Ltd.Unit 204, 205, AZIACenter, No.1233 Lujiazui Ring Rd, Pudong District, Shanghai, China 200120Tel: <86> (21) 5877-1818, Fax: <86> (21) 6887-7858/7898Renesas Technology Hong Kong Ltd.7th Floor, North Tower, World Finance Centre, Harbour City, Canton Road, Tsimshatsui, Kowloon, Hong Kong Tel: <852> 2265-6688, Fax: <852> 2377-3473Renesas Technology Taiwan Co., Ltd.10th Floor, No.99, Fushing North Road, Taipei, Taiwan Tel: <886> (2) 2715-2888, Fax: <886> (2) 3518-3399Renesas Technology Singapore Pte. Ltd.1 Harbour Front Avenue, #06-10, Keppel Bay Tower, Singapore 098632 Tel: <65> 6213-0200, Fax: <65> 6278-8001Renesas Technology Korea Co., Ltd.Kukje Center Bldg. 18th Fl., 191, 2-ka, Hangang-ro, Yongsan-ku, Seoul 140-702, Korea Tel: <82> (2) 796-3115, Fax: <82> (2) 796-2145Renesas Technology Malaysia Sdn. BhdUnit 906, Block B, Menara Amcorp, Amcorp Trade Centre, No.18, Jln Persiaran Barat, 46050 Petaling Jaya, Selangor Darul Ehsan, Malaysia Tel: <603> 7955-9390, Fax: <603> 7955-9510RENESAS SALES OFFICES。

Product data sheet Supersedes data of 1999 Apr 152004 Jan 21DISCRETE SEMICONDUCTORSPNP switching transistorPMBT4403FEATURES•High current (max. 600 mA)•Low voltage (max. 40 V).APPLICATIONS•Industrial and consumer switching applications.DESCRIPTIONPNP switching transistor in a SOT23 plastic package. NPN complement: PMBT4401.MARKINGNote1.* = p : Made in Hong Kong.* = t : Made in Malaysia. * = W : Made in China.PINNINGTYPE NUMBER MARKING CODE (1)PMBT4403*2TPIN DESCRIPTION1base 2emitter 3collectorORDERING INFORMATION LIMITING VALUESIn accordance with the Absolute Maximum Rating System (IEC 60134).Note1.Transistor mounted on an FR4 printed-circuit board.TYPE NUMBER PACKAGENAME DESCRIPTIONVERSION PMBT4403−plastic surface mounted package; 3 leads SOT23SYMBOL PARAMETERCONDITIONSMIN.MAX.UNITV CBO collector-base voltage open emitter −−40V V CEO collector-emitter voltage open base −−40V V EBO emitter-base voltage open collector−−5V I C collector current (DC)−−600mA I CM peak collector current −−800mA I BM peak base current −−200mA P tot total power dissipation T amb ≤ 25 °C; note 1−250mW T stg storage temperature −65+150°C T j junction temperature−150°C T amb operating ambient temperature−65+150°CPNP switching transistorPMBT4403THERMAL CHARACTERISTICS Note1.Transistor mounted on an FR4 printed-circuit board.CHARACTERISTICST amb = 25 °C unless otherwise specified.SYMBOL PARAMETERCONDITIONSVALUE UNIT R th(j-a)thermal resistance from junction to ambientnote 1500K/WSYMBOL PARAMETERCONDITIONSMIN.MAX.UNIT I CBO collector-base cut-off current I E = 0; V CB = −40 V −−50nA I EBO emitter-base cut-off current I C = 0; V EB = −5 V −−50nAh FEDC current gainV CE = −1 V; (see Fig.2)I C = −0.1 mA 30−I C = −1 mA 60−I C = −10 mA 100−V CE = −2 V I C = −150 mA 100300I C = −500 mA20−V CEsat collector-emitter saturation voltageI C = −150 mA; I B = −15 mA −−400mV I C = −500 mA; I B = −50 mA −−750mV V BEsat base-emitter saturation voltage I C = −150 mA; I B = −15 mA −−950mV I C = −500 mA; I B = −50 mA −−1.3V C c collector capacitance I E = I e = 0; V CB = −10 V; f = 1 MHz −8.5pF C e emitter capacitance I C = I c = 0; V EB = −500 mV; f = 1 MHz−35pF f T transition frequency I C = −20 mA; V CE = −10 V; f = 100 MHz 200−MHz Switching times (between 10% and 90% levels); (see Fig.3)t on turn-on time I Con = −150 mA; I Bon = −15 mA; I Boff = 15 mA−40ns t d delay time −15ns t r rise time −30ns t off turn-off time −350ns t s storage time −300ns t ffall time−50nsPNP switching transistor PMBT4403PNP switching transistor PMBT4403 PACKAGE OUTLINEPNP switching transistorPMBT4403DATA SHEET STATUSNotes1.Please consult the most recently issued document before initiating or completing a design.2.The product status of device(s) described in this document may have changed since this document was publishedand may differ in case of multiple devices. The latest product status information is available on the Internet at URL . DOCUMENT STATUS (1)PRODUCT STATUS (2)DEFINITIONObjective data sheet Development This document contains data from the objective specification for product development.Preliminary data sheet Qualification This document contains data from the preliminary specification. Product data sheet ProductionThis document contains the product specification.DISCLAIMERSGeneral ⎯ Information in this document is believed to be accurate and reliable. However, NXP Semiconductors does not give any representations or warranties,expressed or implied, as to the accuracy or completeness of such information and shall have no liability for the consequences of use of such information.Right to make changes ⎯ NXP Semiconductors reserves the right to make changes to informationpublished in this document, including without limitation specifications and product descriptions, at any time and without notice. This document supersedes and replaces all information supplied prior to the publication hereof.Suitability for use ⎯ NXP Semiconductors products are not designed, authorized or warranted to be suitable for use in medical, military, aircraft, space or life support equipment, nor in applications where failure or malfunction of an NXP Semiconductors product can reasonably be expected to result in personal injury, death or severe property or environmental damage. NXP Semiconductors accepts no liability for inclusion and/or use of NXP Semiconductors products in such equipment orapplications and therefore such inclusion and/or use is at the customer’s own risk.Applications ⎯ Applications that are described herein for any of these products are for illustrative purposes only. NXP Semiconductors makes no representation or warranty that such applications will be suitable for the specified use without further testing or modification.Limiting values ⎯ Stress above one or more limiting values (as defined in the Absolute Maximum Ratings System of IEC 60134) may cause permanent damage to the device. Limiting values are stress ratings only and operation of the device at these or any other conditions above those given in the Characteristics sections of this document is not implied. Exposure to limiting values for extended periods may affect device reliability.Terms and conditions of sale ⎯ NXP Semiconductors products are sold subject to the general terms and conditions of commercial sale, as published at /profile/terms, including those pertaining to warranty, intellectual property rightsinfringement and limitation of liability, unless explicitly otherwise agreed to in writing by NXP Semiconductors. In case of any inconsistency or conflict between information in this document and such terms and conditions, the latter will prevail.No offer to sell or license ⎯ Nothing in this document may be interpreted or construed as an offer to sell products that is open for acceptance or the grant, conveyance or implication of any license under any copyrights, patents or other industrial or intellectual property rights.Export control ⎯ This document as well as the item(s) described herein may be subject to export controlregulations. Export might require a prior authorization from national authorities.Quick reference data ⎯ The Quick reference data is an extract of the product data given in the Limiting values and Characteristics sections of this document, and as such is not complete, exhaustive or legally binding.NXP SemiconductorsCustomer notificationThis data sheet was changed to reflect the new company name NXP Semiconductors, including new legal definitions and disclaimers. No changes were made to the technical content, except for package outlinedrawings which were updated to the latest version.Contact informationFor additional information please visit: For sales offices addresses send e-mail to: salesaddresses@© NXP B.V. 2009All rights are reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner.The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license under patent- or other industrial or intellectual property rights.Printed in The Netherlands R75/04/pp7 Date of release: 2004 Jan 21 Document order number: 9397 750 12501分销商库存信息:NXPPMBT4403,215PMBT4403,235。

Key Features:• 20W Output Power• 2:1 Input Voltage Range • 1,500 VDC Isolation• Compact 1 x 2 Inch Case • Single & Dual Outputs • Optional Remote ON/OFF •Industry Standard Pin-OutB2000RW Compact 1 x 2 Inch 20W Wide Input Range DC/DC Con v ert e rsSeriesInputParameter Conditions Min.Typ.Max.Units Input Start Voltage12 VDC Input 8.68.89.0VDC 24 VDC Input 17.017.518.048 VDC Input 34.035.036.0Input Filter␲ (Pi) Filter (Complies with EN55022 Class “A”)Reverse Polarity Input Current 2.0A Short Circuit Input Power3,500mW OutputParameterConditionsMin.Typ.Max.Units Output Voltage Accuracy ±0.5±1.0%Output Voltage Balance Dual Output , Balanced Loads±0.5±2.0%Line Regulation Vin = Min to Max ±0.1±0.3%Load RegulationIout = 10% to 100%±0.1±0.5%Ripple & Noise (20 MHz) (Note 1)5580mV P - P Ripple & Noise (20 MHz)Over Line, Load & Temp.100mV P - P Ripple & Noise (20 MHz)10mV rms Output Power Protection110160%Transient Recovery Time (Note 2)25% Load Step Change150300µSec Transient Response Deviation ±2.0±4.0%Temperature Coeffi cient ±0.01±0.02%/°C Output Short CircuitContinuous (Autorecovery)GeneralParameterConditionsMin.Typ.Max.Units Isolation Voltage60 Seconds1,500VDC Isolation Test Voltage Flash Tested For 1 Sec1,650VDC Isolation Resistance 500 VDC 1,000M ⍀Isolation Capacitance 100 kHz, 1V1,2001,500pF Switching Frequency290330360kHzRemote On/Off (Note 3)Parameter ConditionsMin.Typ.Max.Units Supply On 2.5100.0VDC Supply Off0.01.0VDCStandby Input Current 25mAControl CommonReferenced to Negative Input (pin 2)EnvironmentalParameterConditionsMin.Typ.Max.Units Operating Temperature Range Ambient -40+25+50°C Operating Temperature Range Case+105°C Storage Temperature Range -50+125°C Cooling Free Air ConvectionHumidity RH, Non-condensing95%RFISix-Side Shielded Metal CaseConducted EMI EN55022 Class “A”Physical Case Size 2.0 x 1.0 x 0.40 Inches (50.8 x 25.4 x 10.2 mm)Case Material Metal with Non-Conductive BaseWeight1.06 Oz (30g)Reliability Specifi cationsParameter ConditionsMin.Typ.Max.Units MTBFMIL HDBK 217F , 25°C, Gnd Benign800kHours Absolute Maximum RatingsParameterConditionsMin.Typ.Max.Units Input Voltage Surge (1 Sec)12 VDC Input -0.725.0VDC 24 VDC Input -0.750.048 VDC Input-0.7100.0Lead Temperature1.5 mm From Case For 10 Sec260.0°C Internal Power DissipationAll Models4,500mWCaution: Exceeding Absolute Maximum Ratings may damage the module. These are not continuous operating ratings.MicroPower Direct292 Page Street Suite DStoughton, MA 02072USAT: (781) 344-8226F: (781) 344-8481E: sales@ W: Electrical Specifi cationsSpecifi cations typical @ +25°C, nominal input voltage & rated output current, unless otherwise noted. Specifi cations subject to change without notice.Model Number Input Refl ectedRippleCurrent(mA, Typ)Output OverVoltageProtection(VDC)Effi ciency(%, Typ)CapacitiveLoad(µF Max)Fuse RatingSlow-Blow(mA) Voltage (VDC)Current (mA)Voltage(VDC)Current(mA, Max)Current(mA, Min)Nominal Range Full-Load No-LoadB2001RW129.0 - 18.01,3583050 3.34,000.0240.0 3.9814704,000B2002RW129.0 - 18.01,9843050 5.04,000.0240.0 6.8844704,000B2003RW129.0 - 18.01,898305012.01,670.0100.015.0884704,000B2004RW129.0 - 18.01,903305015.01,340.080.018.0884704,000B2005RW129.0 - 18.01,8983050±12.0±835.0±50.0±15.088±2204,000B2006RW129.0 - 18.01,9033050±15.0±670.0±40.0±18.088±2204,000B2011RW2418.0 - 36.06711730 3.34,000.0240.0 3.9824702,000B2012RW2418.0 - 36.09801730 5.04,000.0240.0 6.8854702,000B2013RW2418.0 - 36.0938173012.01,670.0100.015.0894702,000B2014RW2418.0 - 36.0941173015.01,340.080.018.0894702,000B2015RW2418.0 - 36.09381730±12.0±835.0±50.0±15.089±2202,000B2016RW2418.0 - 36.09411730±15.0±670.0±40.0±18.089±2202,000B2021RW4836.0 - 75.03351020 3.34,000.0240.0 3.9824701,000B2022RW4836.0 - 75.04901020 5.04,000.0240.0 6.8854701,000B2023RW4836.0 - 75.0469102012.01,670.0100.015.0894701,000B2024RW4836.0 - 75.0471102015.01,340.080.018.0894701,000B2025RW4836.0 - 75.04691020±12.0±835.0±50.0±15.089±2201,000B2026RW4836.0 - 75.04711020±15.0±670.0±40.0±18.089±2201,000 Model Selection GuideMechanical DimensionsHeatsink Notes:• Use of the heatsink will extend the units operating temperaturerange by approximately 10°C.• The heatsink is black anodized aluminum.MicroPower DirectWe Power Your Success - For Less!292 Page Street Ste D Stoughton, MA 02072 • TEL: (781) 344-8226 • FAX: (781) 344-8481 • E-Mail: sales@ Heatsink Dimensions (Optional)For heatsink option, add suffi x “H” to model number (i.e. B2003RW-H) For Remote Control option, add suffi x “R” to model number (i.e. B2003RW-R)Mechanical Notes:• All dimensions are typical in inch e s (mm)• Tolerance x.xx = ±0.01 (±0.25)Pin Single Dual1+Vin+Vin2-Vin-Vin3+Vout+Vout4No Pin Comm.5-Vout-Vout6ON/OFF ON/OFFPin ConnectionsDerating CurveNotes:1. When measuring output ripple, it is recommended that an external 1.0 µF ceramic capacitor be placed fromthe +Vout pin to the -Vout pin for single output units and from each output to common for dual output units.2. Transient recovery is measured to within a 1% error band for a load step change of 75% to 100%.3. The maximum control current at the on/off pin (pin 6) during a logic high is 5 µA. The maximum control currentto the on/off pin at logic low is -100 µA. If the on/off pin is left open, the unit operates. If it is grounded, theunit will shut off.4. Operation at no-load will not damage these units. However, they may not meet all specifi cations.5. Dual output units may be connected to provide a 24 VDC or 30 VDC output. To do this, connect the load acrossthe positive (+Vout) and negative (-Vout) outputs and fl oat the output common.6. The converter should be connected to a low ac-impedance source. An input source with a highly inductiveimpedance may affect the stability of the converter. In applications where the converter output loading is highand input power is supplied over long lines, it may be necessary to use a capacitor on the input to insurestart-up.In this case, it is recommended that a low ESR (ESR <1.0 at 100 kHz) capacitor be mounted close to theconverter. For 12V input units, a 22.0 µF is recommended; for 24V & 48V units a 6.8 µF.7. It is recommended that a fuse be used on the input of a power supply for protection. See the table above forthe correct rating.。

TOSHIBA Diode Silicon Epitaxial Planar Type1SS302Ultra High Speed Switching Applicationsz Small package : SC-70z Low forward voltage : V F (3) = 0.90V (typ.) z Fast reverse recovery time : t rr = 1.6ns (typ.)z Small total capacitance : C T = 0.9pF (typ.)Absolute Maximum Ratings (Ta = 25°C )Characteristic Symbol Rating UnitMaximum (peak) reverse voltage V RM 85 V Reverse voltageV R 80 V Maximum (peak) forward current I FM 300 (*) mA Average forward current I O 100 (*) mA Surge current (10ms) I FSM 2 (*) A Power dissipation P100mWJunction temperature T j 125 °CStorage temperatureT stg−55~125 °CNote: Using continuously under heavy loads (e.g. the application of high temperature/current/voltage and thesignificant change in temperature, etc.) may cause this product to decrease in the reliability significantly even if the operating conditions (i.e. operating temperature/current/voltage, etc.) are within the absolute maximum ratings.Please design the appropriate reliability upon reviewing the Toshiba Semiconductor Reliability Handbook (“Handling Precautions”/“Derating Concept and Methods”) and individual reliability data (i.e. reliability test report and estimated failure rate, etc). *: Unit rating. Total rating = unit rating × 0.7Electrical Characteristics (Ta = 25°C )Characteristic SymbolTestCircuitTest ConditionMinTyp.MaxUnitV F (1)― I F = 1mA ― 0.60 ― V F (2) ― I F = 10mA ― 0.72 ― Forward voltageV F (3)― I F = 100mA ― 0.90 1.20VI R (1) ― V R = 30V ― ― 0.1Reverse current I R (2) ― V R = 80V ―― 0.5μATotal capacitance C T ― V R = 0, f = 1MHz ― 0.9 3.0 pF Reverse recovery timet rr―I F = 10mA, Fig.1― 1.6 4.0 nsJEDEC ― EIAJ SC-70TOSHIBA 1-2P1CWeight: 0.006g Unit: mmMarkingFig.1 Reverse Recovery Time(t rr ) Test CircuitRESTRICTIONS ON PRODUCT USE20070701-EN GENERAL •The information contained herein is subject to change without notice.•TOSHIBA is continually working to improve the quality and reliability of its products. Nevertheless, semiconductor devices in general can malfunction or fail due to their inherent electrical sensitivity and vulnerability to physical stress. It is the responsibility of the buyer, when utilizing TOSHIBA products, to comply with the standards of safety in making a safe design for the entire system, and to avoid situations in which a malfunction or failure of such TOSHIBA products could cause loss of human life, bodily injury or damage to property.In developing your designs, please ensure that TOSHIBA products are used within specified operating ranges as set forth in the most recent TOSHIBA products specifications. Also, please keep in mind the precautions and conditions set forth in the “Handling Guide for Semiconductor Devices,” or “TOSHIBA Semiconductor Reliability Handbook” etc.• The TOSHIBA products listed in this document are intended for usage in general electronics applications (computer, personal equipment, office equipment, measuring equipment, industrial robotics, domestic appliances, etc.).These TOSHIBA products are neither intended nor warranted for usage in equipment that requires extraordinarily high quality and/or reliability or a malfunction or failure of which may cause loss of human life or bodily injury (“Unintended Usage”). Unintended Usage include atomic energy control instruments, airplane or spaceship instruments, transportation instruments, traffic signal instruments, combustion control instruments, medical instruments, all types of safety devices, etc.. Unintended Usage of TOSHIBA products listed in his document shall be made at the customer’s own risk.•The products described in this document shall not be used or embedded to any downstream products of which manufacture, use and/or sale are prohibited under any applicable laws and regulations.• The information contained herein is presented only as a guide for the applications of our products. No responsibility is assumed by TOSHIBA for any infringements of patents or other rights of the third parties which may result from its use. No license is granted by implication or otherwise under any patents or other rights of TOSHIBA or the third parties.• Please contact your sales representative for product-by-product details in this document regarding RoHS compatibility. Please use these products in this document in compliance with all applicable laws and regulations that regulate the inclusion or use of controlled substances. Toshiba assumes no liability for damage or losses occurring as a result of noncompliance with applicable laws and regulations.。

Switch FunctionSPST- 2 through 10 and 12 positions Switch Contact ResistanceInsulation Resistance1,000 megohms minimum between insulated terminals Dielectric Strength500 VDC for 1 minute between adjacent switchesNonswitching Rating100 mA or 50 VDC maximumSwitch Capacitance5 pF maximum between adjacent closed switches Operating Temperature –40°C to +85°CActuation LifeSeries 209: 2,000 cycles switching @ 100 mA, 20 VDC or @ .1 mA, 5 VDC (dry circuit)Series 210: 1,000 cycles switching @ 100 mA, 20 VDC or @ .1 mA, 5 VDC (dry circuit)Allowable Solder Time Up to 5 seconds at 260°C VibrationPer MIL-STD-202F, method 204D, condition B (.06" or 15 G’s between 10 HZ to 2K HZ) with no contact inconsistencies greater than 1 microsecond.ShockPer MIL-STD-202F, method 213B, condition A (50 G’s) with no contact inconsistencies greater than 1 microsecond.SealingStandard bottom seal Optional top tape sealElectrical and Mechanical SpecificationsSeries 209 – Premium AUTO-DIP Switches Series 210 – Economical AUTO-DIP Switches•RoHS compliant1-2 CTS Electronic ComponentsSwitch Serie sInitial, max .End of life, max.20925 milliohms 50 millohms 210100 milliohms 500 millohmsPackagingStandard :Anti-Static tube packaging© 2008 CTS Corporation. All rights reserved. Information subject to change.2/19/08CTS AUTO-DIP ®SERIES CON T ACT FE A TURES1.Value of Redundant (Bifurcated)Contacts:Redundancydramatically reduces the probability of contact failure, IMPROVING RELIABILITY.2.Value of Wiping Contact Action:Clean contact area, IMPROVING RELIABILITY.3.Value of Contactor Not Deflecting During Actuation : Constant contact pressure eliminates overstressing contacts, IMPROVING RELIABILITY.4.Value of Detent Separate from Contactor:Separate detent allows optimization of nondeflecting contactor and detent designs, IMPROVING RELIABILITY.Ordering Information209/210M STXX :NO. OF POSITIONM :MEDIUM ACTUATOR(0.25mm/.010”)LP :LOW PROFILE (Flush)T :TOP TAPE SEALS :BOTTOM SEAL12Not available on Extended actuator**E : EXTENDED HEIGHT ACTUATOR(0.6mm/.024”) F : SHIP AT OFF POSITIONBLANK : SHIP AT ON POSITION FD–D :STRAIGHT TERMINALBLANK :AUTO-INSERTABLE TERMINAL 2-2 CTS Electronic Components © 2008 CTS Corporation. All rights reserved. Information subject to change.2/19/082. Wiping contact action1. Redundant (bifurcated) cross radial contactor 3. Contactor does not deflect during actuation4. Detent separate from contactorBLANK : NO TOP TAPE SEAL。

• 3W Isolated Output • 4 : 1 Input Range• 24-Pin DIP Package• Regulated Outputs• Efficiency to 80%• Pi Input Filter• Continuous Short Circuit ProtectionMODEL INPUT OUTPUT OUTPUT INPUT CURRENT % EFF.CASE NUMBER VOLTAGE VOLTAGE CURRENT NO LOAD FULL LOAD3AW-013AW-023AW-033AW-04 3AW-05 3AW-06 3AW-07 3AW-11 3AW-12 3AW-13 3AW-14 3AW-15 3AW-16 3AW-179-36VDC18-72VDC5 VDC12 VDC15 VDC±5 VDC±12 VDC±15 VDC3.3 VDC5 VDC12 VDC15 VDC±5 VDC±12 VDC±15 VDC3.3 VDC600 mA250 mA200 mA±300 mA±125 mA±100 mA600 mA600 mA250 mA200 mA±300 mA±125 mA±100 mA600 mA15 mA15 mA15 mA25 mA25 mA25 mA15 mA7.5 mA7.5 mA7.5 mA12 mA12 mA12 mA7.5 mA174 mA165 mA165 mA179 mA174 mA174 mA117 mA87 mA78 mA78 mA88 mA87 mA87 mA58 mA7276767072727072808071727270AA1SpecificationsINPUT SPECIFICATIONS:Input Voltage Range........................................................................................................................................24V ..................................................................9-36V48V ................................................................18-72VInput Filter...................................................................................................................................................................................................................................Pi TypeOUTPUT SPECIFICATIONS:Voltage Accuracy .............................................................................................................................................................................................................±2.0% max.Voltage Balance (Dual)................................................................................................................................................................................................±1.0% / max.Temperature Coefficient..................................................................................................................................................................................................±0.05% /˚C Ripple and Noise,20MHz BW,Single & ±5V ............................................................................................................................................................100mV p-p max.Dual................................................................................................................................................................................................1% p-p max.Short Circuit Protection.....................................................................................................................................................................................................Continuous Line Regulation 1,Single/Dual...........................................................................................................................................................................................±0.5% max.Load Regulation,Single 2..................................................................................................................................................................................................±0.5% max.Dual 3...................................................................................................................................................................................................±1% max.GENERAL SPECIFICATIONS:Efficiency ...............................................................................................................................................................................................................................See Table Isolation Resistance ..............................................................................................................................................................................................................109Ohms Switching Frequency ........................................................................................................................................................................................................100kHz min.Operating Temperature Range..................................................................................................................................................................................-25˚Cto +71˚C Case Temperature (Plastic case).....................................................................................................................................................................................95˚C max.(Copper case)..............................................................................................................................................................................100˚C max.Cooling................................................................................................................................................................................................................Free-Air Convection Storage Temperature Range ..................................................................................................................................................................................-40˚C to +100˚C Dimensions........................................................................................................................................................................................................1.25 x 0.8 x 0.4 inches(31.8 x 20.3 x 10.2 mm)ISOLATION VOLTAGE:500 VDC min............................................................................................................................................................................................................Standard Models3K VDC min 4..............................................................................................................................................................................................................Suffix "H" ModelsCASE MATERIAL:Standard Models................................................................................................................................................................................Non-Conductive Black Plastic Suffix "M" Models 5....................................................................................................................................................................................Black Coated Copper withNon-Conductive Base 3A WAll Specifications Typical At Nominal Line,Full Load and 25˚C Unless Otherwise Noted.CASE APIN CONNECTION500 VDC (1.5K & 3K) VDCPin Single Dual Output Output Pin Single DualOutput Output 1235910111213141516222324+V Input NC NC NP NP -V Output +V Output -V Input -V Input +V Output -V Output NP NC NC +V Input+V Input -V Output Common NP NP Common +V Output -V Input -V Input +V Output Common NP Common -V Output +V Input1235910111213141516222324NP -V Input -V Input NP NC NC NC NP NP +V Output NC -V Output +V Input +V Input NPNP -V Input -V Input NP Common NC -V Output NP NP +V Output NC Common +V Input +V Input NP*NP-NO PIN *NC-NO CONNECTION WITH PINNOTE:1.Measured From High Line to low Line2.Measured From Full Load to 10% Load3.Measured From Full Load to 1/4 Load4.Non-Conductive Black Plastic Only5.Suffix "HM" 1.5KVDC Instead of 3KVDC Isolation24532 Telephone Road Suite 103 Ventura, CA 93003 80 Cabot Court Hauppauge, NY 11788(805 ) 642-0660 (800)456-2006 Fax (805) 642-0790 e-mail: sales@ (631)435-0410 (800)874-6727 Fax(631)951-4341BEHLMANWeb-site: 。

可控硅参数符号说明: IT(AV)--通态平均电流VRRM--反向重复峰值电压IDRM--断态重复峰值电流ITSM--通态一个周波不重复浪涌电流VTM--通态峰值电压IGT--门极触发电流VGT--门极触发电压IH--维持电流dv/dt--断态电压临界上升率di/dt--通态电流临界上升率Rthjc--结壳热阻VISO--模块绝缘电压Tjm--额定结温VDRM--通态重复峰值电压IRRM--反向重复峰值电流IF(AV)--正向平均电流KP200A—500A平板型普通晶闸管参数KP2000A—4500A平板型普通晶闸管参数KK200A—1000A 平板型快速晶闸管KP800A—1500A 平板型普通晶闸管参数KK1200A—3000A 平板型快速晶闸管Type V DRMV RRMI T(AV)@85℃tq@100℃30V/μSV TM@I TM(max)I GT V GTI DRMI RRM(max)I H(max)TjmI TSM@10msI2t@10msdv/dt(min)di/dt(min)Rthjc(max)外形(V)(A)(μS)(V/A)(mA)(V)(mA)(mA)℃(KA)(KA2S)(V/μS)(A/μS)(℃/W)KK1200-55KT14800-1800120015-35 3.1/300040-3000.9-2.56020-400115149805003000.024KT14 KK1500-60KT151200-2600150020-60 3.1/300040-3000.9-3.06020-5001151613005003000.02KT15 KK1800-67KT9B1200-2600180015-60 3.1/400040-3000.9-3.06020-5001151918005003000.017KT9B KK2000-70KT161200-2600200015-60 3.1/400040-3500.9-3.08020-8001152122005003000.016KT16 KK2500-76KT171200-2600250015-60 3.1/500040-3500.9-3.08020-8001152736005003000.011KT17 KK3000-76KT17800-1600300020-60 3.1/500040-3500.9-3.08020-8001153148005003000.011KTKP5A—500A 螺栓型普通晶闸管参数KK5A—100A 螺栓型快速晶闸管大功率可控硅晶闸管系列硅双向触发二极管参数可控硅整流器件单、双向可控硅（SCR,TRIAC）YCR单向可控硅系列◆先进的玻璃钝化芯片◆小的通态压降◆高的可靠性、稳定性KS5A—50A螺栓型双向晶闸管KG5A—50A螺栓型高频晶闸管目前国产可控硅的型号有部颁新、旧标准两种，新型号将逐步取代旧型号。

50.0kHz 90 V AC 0.6265 V AC 0.41mH 50 Hz 1.00mH (0.21mH<Lnom<2.98mH)0.46A 5 V 0.419A Full Wave Rectification 400 mA 0.30Half Wav e Rectif ication 0.8A/mm KP32100.6KP32100.0178cm EE102.50W 12.1mm 1.00126Turns 5.00μF 0.29mm 4.7μF 89.40V10.00kΩ16.00kΩ (Rdummy >2.1kΩ)0.011.00Ω0.10Ω1.25Ω1.20ΩComponent ValueC in 4.7μFC 220.0μFC dd 1.0μFC 1.0μFL 1.0 mHR sen 1.2 ΩR fb110.0 kΩR fb218.5 kΩR dummy 16.0 kΩD11A/600VD2FF1MSIC KP3210input parameter for customer 输Non-isolated Buck Regulator Design using KP321XMinimum RMS Line Voltage (V in_min ，最低输入电压Calculated Result for Circuit Key Component 计算Typical Application Circuit （典型应用电路）Maximum RMS Line Voltage (V in_max ，最高输入电压Min Saturated Current of Inductor (I sat ，电感最低饱和电流2. Buck Inductor Design (电感设计1. Define System Specifications （系统规格）Calculated Ty pe Inductance Value (L nom_type ，典型电感值Ty pical Switching Frequency (F sw_type ，满载典型开关频率Input Specification (输入规格):Inductor Current Ripple Coef icient (k ，电感电流纹波系数Line Frequency (F ac ，输入电压频率Select Inductor Value (L nom ，电感值选择Output Specification (输出规格):Rated DC Output Current (I ，额定输出电流Estimated Sy stem Ef iciency (η，系统效率预估，%)Core AP Value(A ，磁芯AP值Normal Output Voltage (V ，额定输出电压Max Flux Density (B max ，最大磁通密度Recommended IC (推荐IC)IC Selection (IC 选择RMS Current of Inductor (I rms ，电感电流有效值Select Current Sensing Resistor Value (R cs ，采样电阻选择Core=EE10, N=126 (0.29mm ),Isat>0.46A Electroly tic Cap,400V 1206, Film Resistor, 1%Minimum DC Input Voltage (V indc_min ，整流桥后最低输入电压Maximum Current Sensing Resistor Value (R cs_max ，最大采样电阻Minimum Current Sensing Resistor Value (R cs_min ，最小采样电阻Max ESR of Output Capacitor (R esr_max ，输出电容ESR最大值Sensing Resistor Selection (采样电阻选择):Cin is OK!Dummy Resistor (R dummy ，假负载电阻Vo ripple Coef icient (k ，输出电压纹波系数FB Lower Resistor Value Selection (R FB1，R FB1电阻K rp & K iL 输出电压与电感电流纹波系数High Perf ormance Low Cost Of -line PWM Power Switch Fast Recov ery Diode,Vrrm>375V 4. Bom of Key Components （关键器件参数表）Description Film Resistor, 1%1206, Film Resistor, 5%Electroly tic Cap, ESR<0.1ΩCeramic Cap, X7R Ceramic Cap, X7R Film Resistor, 1%Fast Recov ery Diode,ID>0.46A, Vrrm>375V Minimum Needed Input Capacitor (C IN ，最小输入电容预估Calculated Input Power (P ，输入功率计算Selected Input Capacitor Value(C IN ，输入电容选择Max Current Density of Coil (K ，最大电流密度Bobbin Fill Factor(K ，骨架填充系数3. Other Parameters （其他参数）Select Core Ty pe (磁芯选择Ef ectiv e Cross-Sectional Area (A ，磁芯有效截面积Total Winding Turns Number (N ，线圈匝数Recommended Winding Diameter (线圈直径Selected Rectif ication Ty pe (整流桥类型选择Input Bulk Capacitor Selection (输入电容选择):Full Wave Rectification HV DCInput KP321X Cvdd RcsTypical Application Cirtuit 1:Vout>10VHV DCInput Cvdd RcsKP321Vout Vout 备注默认输出电压12V 时，需悬空HV DC Input VoutDrain GND CS Drain Drain FB VDD KP321XCvdd Rcs DrainTypical Application Cirtuit 2:Vout<10V HV DC InputVoutCvdd Rcs NC GND FB HVGATENC VDD KP321CSL_MID L_PP L_PP L_MID=V =V & k。

ucp210负载参数UCP210是一种常见的插入式带座球轴承，广泛应用于各种机械设备和工业过程中。

在了解UCP210的负载参数之前，先来了解一下UCP210的结构和组成部分。

UCP210插入式带座球轴承由外球面轴承和带座座托架组成。

外球面轴承是球轴承的一种，由内圈、外圈、钢球和保持架等部分组成。

带座座托架通常是由铸铁或冲压钢板制成，它有两部分：上座和底座。

上座用于安装外球面轴承，而底座用于固定在机械设备上。

正如其名称所示，UCP210支持插入式安装。

这意味着它可以通过将外球面轴承插入到座托架的上座部分来进行安装。

然后，通过螺栓将底座固定在机械设备上，以确保轴承在工作时的稳定性和可靠性。

UCP210具有较高的负载承受能力，主要由外球面轴承的结构和材料决定。

外球面轴承通常采用优质钢材制成，经过热处理和精密加工，以提高其硬度和耐磨性。

这使得UCP210能够承受相对较大的径向负载和轴向负载。

UCP210的负载参数可以从制造商提供的技术规格表中获得。

这些参数包括额定动载荷、额定静载荷和动态等效负荷。

额定动载荷是指轴承在标准工况下能够承受的最大动态负荷。

额定静载荷是指轴承在不转动状态下能够承受的最大静态负荷。

动态等效负荷是指当轴承在旋转条件下承受径向和轴向负载时，将径向负载和轴向负载转化为等效径向负载的方法。

除了负载参数之外，UCP210还有其他重要的性能参数，如转速限制、密封方式和润滑方式。

转速限制是指轴承能够承受的最高转速。

密封方式和润滑方式影响轴承的密封性能和润滑效果，进而影响轴承的寿命和性能。

通过了解UCP210的负载参数和其他性能参数，可以选择合适的轴承，并确保其能够正常工作并满足机械设备的需求。

在使用UCP210时，还需要注意正确的安装和维护，以提高其使用寿命和性能。

Absolute Pressure Sensor KP123Data SheetRev 1.02Edition 2007-11-23Published byInfineon Technologies AG81726 München, Germany© 2007 Infineon Technologies AGAll Rights Reserved.Legal DisclaimerThe information given in this document shall in no event be regarded as a guarantee of conditions or characteristics. With respect to any examples or hints given herein, any typical values stated herein and/or any information regarding the application of the device, Infineon Technologies hereby disclaims any and all warranties and liabilities of any kind, including without limitation, warranties of non-infringement of intellectual property rights of any third party.InformationFor further information on technology, delivery terms and conditions and prices, please contact the nearest Infineon Technologies Office ().WarningsDue to technical requirements, components may contain dangerous substances. For information on the types in question, please contact the nearest Infineon Technologies Office.Infineon Technologies components may be used in life-support devices or systems only with the express written approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure of that life-support device or system or to affect the safety or effectiveness of that device or system. Life support devices or systems are intended to be implanted in the human body or to support and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may be endangered.1Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 1.1Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 1.2Product Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 2Pin Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 3Functional Block Diagram. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 4Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 4.1Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 4.2Transfer Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 5Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 5.1Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 5.2Operating Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 5.3Sensor Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 5.4Electrical Details . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 5.4.1Output Voltage versus Load . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 5.4.2Timings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 6Accuracy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 6.1Supply Voltage Influence (Ratiometric Error) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 6.2Overall Accuracy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 7Application Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 8Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 9Package Outlines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 9.1Package Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 9.2Cap dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 9.3Footprint . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 10EMC Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 10.1EM Immunity by Direct Power Injection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 10.2EM Immunity by Electrical Fast Transients . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 11Identification Code. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23Absolute Pressure SensorRevision History: 2007-11-23, Rev 1.02Previous Version: Rev 0.1Page Subjects (major changes since last revision)Page 5Feature “green” package added.Page 5Paragraph about pressure range rephrased.Page 10ESD robustness corrected.Symbol for input pressure range (max and operating) added/changed.Page 10Page 11Page 12Junction temperature added.Page 15Definition ratiometric error rephrased. Formula added.Misspelling corrected.Page 17Page 23Page 19Drawing updated.Page 19“Green” compliancy added in package chapter.Page 22Chapter EMC added.Page 23Chapter identification code added.Previous Version: Rev 0.9Page 17Changes in recommended application circuit.Page 18Reorganization of chapters package outlines and cap.Page 19Previous Version: Rev 1.0Page 6Changes according to application circuit for GND connection and digital PINs. Previous Version: Rev 1.01Page 12Correction of sensor characteristics output referred noise.We Listen to Your CommentsAny information within this document that you feel is wrong, unclear or missing at all? Your feedback will help us to continuously improve the quality of this document.Please send your proposal (including a reference to this document) to:sensors@Product Name Product Type Ordering Code Package KP123Absolute Pressure Sensor SP000239576PG-DSOF-8-12Absolute Pressure SensorKP1231Overview1.1Features•Ratiometric analog output •Calibrated transfer function•High accuracy over a large temperature range •Typical error ± 1.5% Full Scale Range •“Green” 8-pin SMD housing•On Board Diagnostics (OBD) for broken wire detection1.2Product DescriptionThe KP123 is a miniaturized Absolute Pressure Sensor IC based on the capacitive principle. It is surface micromachined with a monolithic integrated signal conditioning circuit implemented in BiCMOS standard technology. Because the KP123 is a high-precision IC for cost-critical solutions, the chip is packaged in a “green” low-cost SMD housing. The sensor is developed for measurement of barometric air pressure (BAP).High accuracy and high sensitivity enable the deployment of this device in consumer applications.The calibrated transfer function converts a pressure range from 15 kPa po12.5 kPa into an analog output voltage between 0.2 V>>BDCand 4.7>>BDCV.Pin Configuration 2Pin ConfigurationTable 1Pin Definitions and FunctionsPin Function1TEST Test pin 1)2CLOCK / V PROG External Clock for Communication / Programming Voltage 1)3DATA IN Serial data input pin 1)4DATA OUT Serial data output pin 1)5V DD Supply Voltage6GND0 Volt circuit ground potential 2)7V OUT Analog pressure signal output8GND Alternative ground pin 2)1)Digital pins are used only during calibration and test. It is recommended to leave these PINs floating.2)It is recommended to connect both GND PINs.Functional Block Diagram3Functional Block DiagramFigure 2Block DiagramV DDCLOCK /V DATA IN GNDDATA OUT4Functional Description4.1SensorPressure is detected in a capacitive way by an array of surface micromachined sensor cells.The sensor cell output is amplified, temperature compensated and linearized to obtain an output voltage that is proportional to the applied pressure.The transfer function for linearization is calculated in the digital part of the sensor using third order polynomial calculation.The transfer function is given by the following parameters:•Minimum and maximum rated pressure•Voltage at minimum rated pressure•Voltage at maximum rated pressure•SensitivityThe output is analog and ratiometric with respect to the supply voltage.All parameters needed for the complete calibration algorithm — such as offset, gain, temperature coefficients of offset and gain, and linearization parameters — are determined after assembly. The parameters are stored in internal registers in the EEPROM of the chip.On Board DiagnosticsWhen the chip is not powered properly, the JFET transistors of the On Board Diagnostics (OBD) stage are self-conducting. For example, if the GND connection is interrupted, the output is drawn strongly to V DD. The microcontroller can set a limit for valid output signals. In the case of an error, the output voltages will be too close to the V DD or GND potential.4.2Transfer FunctionThe KP123 device is fully calibrated on delivery. The sensor has a linear transfer function between the applied pressure and the output signal:The output is ratiometric.Gain a and Offset b are determined during calibration in order to create the required transfer function.Standard Transfer FunctionThe following calibration is adjusted with the parameters a and b :Note:The application circuitry determines the current driven by the device and thus has an impact on thediagnostic ranges.Table 2Transfer Function (End Points)Pressure Output Voltage @ V DD = V DD;TYPSymbolValues Unit SymbolValues Unit P IN,MIN 15kPaV OUT,MIN 0.2VP IN,MAX 115V OUT,MAX4.7V OUT =V DD x (a x P + b)Electrical Characteristics5Electrical Characteristics5.1Absolute Maximum RatingsAttention:Stresses above the max. values listed here may cause permanent damage to the device.Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Maximum ratings are absolute ratings; exceeding only one of these values may cause irreversible damage to the integrated circuit.Table 3Absolute Maximum RatingsParameterSymbolValues UnitNote / Test ConditionMin.Typ.Max.Supply voltageV DD– 0.3– 6.5V––16.51h @ 70°C – 6.5 1)1)Reverse polarity; I DD < 300mA––for max. 5 minutesOutput voltage V OUT – 0.3 –V DD + 0.3VMaximum ambient temperature T A – 20100°C Storage temperature T S – 60150°C Maximum input pressure rangeP MAX405.8–60087kPa psi for max. 5 minutes405.8–15021.75kPa psi Voltage at CLOCK / V PROG Pin V CLK ––20V Voltage at data pins (DATA IN, DATA OUT)V DATA–– 5.0V ESD robustness 2)2)HBM: 1.5k Ω, 100pF; according to EIA/JESD22-A114-B (covers MIL STD 883D)V ESD, HBM ––± 2kV Analog pins:V DD , Vout, GND ––± 2kVDigital pins:CLOCK / V PROG, DATA OUT, DATA IN5.2Operating RangeThe following operating conditions must not be exceeded in order to ensure correct operation of the device.All parameters specified in the following sections refer to these operating conditions, unless otherwise noticed.Table 4Operating RangeParameter SymbolValues UnitNote / Test ConditionMin.Typ.Max.Supply voltage V DD 4.55 5.5V V OUT is ratiometric to V DDOutput current 1)1)Negative values: Current into device (pull-up resistor used).Positive values: Current out of the device (pull-down resistor used).I OUT – 1–1mA Maximum ambient temperature T A – 20100°C Input pressure rangeP IN405.811516.7kPa psi5.3Sensor CharacteristicsTable 5Sensor CharacteristicsParameterSymbolValues Unit Note / Test ConditionMin.Typ.Max.Output Voltage Range V OUT_R 0.10 4.85V More information in chapter“Electrical Details” on Page 13Sensitivity S –45–mV/ kPa Supply current I DD –810mA 1)1) A peak supply current of up to 22 mA is possible during power up.Overall Accuracy Error Err –± 1.5–%FSS (Full Scale Span) 2)2)More details in chapter “Overall Accuracy” on Page 16Ratiometric Error E RAT –25–25mV 3)3)More details in “Supply Voltage Influence (Ratiometric Error)” on Page 15Output referred noise V NOISE –– 2.5mV RMS@ f > 1kHz 4))4)200 measurements in sequence, bandwidth limited to 40kHz –– 1.8@ f < 1kHzResponse time 5)5)More details in “Timings” on Page 14t R – 1.8–ms 10% to 90% of the final output valueStabilization time 5)t S ––10ms For full accuracyPower up time 5)t UP ––5ms 90% of the final output valueBroken wire: diagnosis response time 6)6)In the event of a broken wire (broken V DD line or broken GND line), the output changes to certain voltage levels within the broken wire response time.t OBD ––1ms OBD Transistor On ResistanceR DSON ––160ΩV OUT to V DD or V OUT to GND,@ 25°CJunction temperature 7)7)T junction = T ambient + ∆T c,j (in steady-state condition, typical operation conditions)T j– 10.2109.8°C Thermal resistanceR thj-amb245K/W5.4Electrical Details5.4.1Output Voltage versus LoadThe output voltage limits depend on:•the value of the external load resistor•the connection mode (pull-up or pull-down)Figure 4Maximum Output Voltage Limit at Maximum Rated Pressure with Pull-Down LoadFigure 5Minimum Output Voltage Limit at Minimum Rated Pressure with Pull-Up Load Note:The values in the diagrams are valid for the entire specified temperature range.5.4.2TimingsPower-up TimeThe power-on time t UP is defined as the maximum time between the supply voltage reaching its operating range and the output voltage reaching 90% of its final value.Figure 6Power-up TimeResponse Time and Stabilization TimeThe Response Time t R is defined as the time for the incremental output change to go from 10% to 90% of its final value after a specified pressure step.The Stabilization Time t S is defined as the time required for the output voltage to meet the specified accuracy after the pressure has been stabilized.Figure 7Response Time and Stabilization Time6AccuracyThe accuracy of the KP123 sensor is influenced by the supply voltage (ratiometric error) and by pressure, temperature and aging. The specified value represents the theoretical value, when the actual pressure is multiplied with the transfer function, see Figure 3. The error equals the deviation between the measured output voltage value and the specified output voltage value.6.1Supply Voltage Influence (Ratiometric Error)DefinitionIdeally, the sensor is ratiometric – the output (V OUT ) scales by the same ratio that V DD increases or decreases. The ratiometric error is defined as the difference between the ratio that V DD changed and the ratio that V OUT changed, expressed as a percentage:The output voltage V OUT is ratiometric to V DD , within the range provided in Table 2.V DD must be within the operating range specified in Table 4.Figure 8Ratiometric ErrorTable 6Ratiometric ErrorSupply Voltage (V)Max. Ratiometric Error (% of V DD,TYP )V DD,MIN ± 0.5V DD,TYP 0V DD,MAX± 0.5E RAT (%) =V OUT (@V DD ) - V OUT (@5V) x5VV DD 5Vx 100%6.2Overall AccuracyOverall accuracy covers the entire pressure and temperature range from all sources of error including the following:•Pressure:Output deviation from target transfer function over the specified pressure range.•Temperature:Output deviation over the temperature range.•AgingAll drifting parameters during operating time.Note:Ratiometric signal error is not included in the overall accuracy. For error measurements, the supply voltage must have the nominal value (V DD = V DD,TYP).The error band is determined by three continuous lines through four relevant break points:Table 7AccuracyTemperature Point (°C)Typical Error (kPa)Error Multiplier– 20± 4.530± 1.5185± 1.51100± 2.625 1.75Figure 9Error Multiplier over TemperatureApplication Circuit7Application CircuitIt is recommended to protect the KP123 pressure sensor IC against overload voltage and electro-magnetic interference (as shown in Figure 10).The output circuitry acts as a low-pass decoupling filter between the sensor IC output and the A/D input of the microcontroller.Figure 10Application Circuitry for EvaluationNote:It is recommended to leave digital PINs CLOCK/V PROG , DATA IN and DATA OUT floating. If these PINs aregrounded, it is recommended to connect both GND PINs.Note:The value of load resistor R 1 or R 2 determines the current driven by the device.Table 8Component ValuesComponentSymbolValues UnitNoteMin.Typ.Max.Pull-Up Resistor R 1559100k ΩOnly 1 resistor allowedPull-Down Resistor R 2559100k ΩLow Pass Resistor R 3 3.922100k ΩSupply Blocking Capacitor C 110100100nF Output Blocking Capacitor C 20100100nF Low Pass CapacitorC 310100100nFPackage8PackageAs well as using “green” materials, the P G-DSOF-8-12 package is optimized regarding mechanical stress influences. The package fulfills the solder conditions for lead-free board assembly.In the application it is recommended to ensure that the same pressure is applied to the whole package.The KP123 is supplied with a removable plastic cap (refer to Figure 12). The flat surface of this cap on top of the package allows handling with standard pick-and-place tools.After soldering the device to the printed circuit board (PCB), the cap on the PG-DSOF-8-12 may be removed. When removing the protective cap, care should be taken to avoid damage to the device.In some applications, such as for barometric measurements, it may be appropriate to leave the protective cap on the package after the soldering process. Damage to the gel is prevented. The four splits in the cap side allow a sufficient pressure coupling.9Package Outlines 9.1Package DimensionsFigure 11Package9.2Cap dimensionsFigure 12Cap DimensionsPackage Outlines 9.3FootprintEMC Requirements 10EMC Requirements10.1EM Immunity by Direct Power InjectionThe KP123 test is compliant to EMC requirements for Direct Power Injection (DPI) described in•ISO 11452-7 11-95•IEC 62132-3 01-00.10.2EM Immunity by Electrical Fast TransientsThe KP123 test is compliant to EMC requirements for Electrical Fast Transients (EFT) according to the hardware set up shown in Figure 14, which is based on•ISO 7637-1 08-00•ISO/CD 7637-2 02-99•ISO 7637-3 11-95SensorFigure 14Hardware Set Up for Electrical Fast TransientsIdentification Code11Identification CodeThe identification code is provided in a machine-readable format. The date and sales code are provided in human-readable format.Figure 15Sensor Identification CodeThe marking for the KP123 is on the same side of the package as pin 8.Date code definition:WW: work week (1…53)YY: year (06…99)Data Matrix Code: 8 x 18 Dots, Dot Size: 0.15 mm x 0.15 mm。